Regulatory Cascade Research Articles

The intestine-specific homeobox (ISX) modulates β-carotene-dependent regulation of microsomal triglyceride transfer protein (MTP) in a tissue-specific manner

Vitamin A is an essential nutrient crucial to ensuring proper mammalian embryonic development. β-Carotene is the most prevalent form of vitamin A in food that, when transferred in its intact form from mother to the developing tissues, can serve as an in situ source of retinoic acid, the active form of vitamin A. We have previously provided evidence that the maternal-fetal transfer of β-carotene across the placenta is mediated by lipoproteins and that β-carotene itself regulates placenta lipoprotein biogenesis by means of its derivatives β-apo-10′-carotenoids and retinoic acid. These metabolites exert antagonistic transcriptional activity on placental microsomal triglyceride transfer protein (MTP) and apolipoprotein B (APOB), two key players of lipoprotein biosynthesis. Here, we analyzed the time-dependency of this regulation over the course of 24 h upon a single maternal administration of β-carotene. We also tested the hypothesis that the transcriptional repressor intestine-specific homeobox (ISX) plays a role in the regulation of Mttp in placenta. We observed that ISX is expressed in placenta of mouse dams and is regulated by β-carotene availability. Furthermore, we demonstrated that the absence of Isx disrupts the β-carotene-mediated regulation of placental MTP. We also showed that this mechanism is organ-specific, as it was not observed in enterocytes of the intestine, a major place of Isx expression. Therefore, we identified ISX as a “master” regulator of a placental β-carotene-dependent transcriptional regulatory cascade that fine-tunes the flux of provitamin A carotenoid towards the developing fetus.

Genomic Insights into Host Susceptibility to Periprosthetic Joint Infections: A Comprehensive Literature Review

Periprosthetic joint infection (PJI) is a multifactorial disease, and the risk of contracting infection is determined by the complex interplays between environmental and host-related factors. While research has shown that certain individuals may have a genetic predisposition for PJI, the existing literature is scarce, and the heterogeneity in the assessed genes limits its clinical applicability. Our review on genetic susceptibility for PJI has the following two objectives: (1) Explore the potential risk of developing PJI based on specific genetic polymorphisms or allelic variations; and (2) Characterize the regulatory cascades involved in the risk of developing PJI. This review focused on clinical studies investigating the association between genetic mutations or variations with the development of PJI. The genes investigated in these studies included toll-like receptors and humoral pattern recognition molecules, cytokines, chemokines, mannose-binding lectin (MBL), bone metabolism molecules, and human leukocyte antigen. Among these genes, polymorphisms in IL-1, MBL, vitamin D receptors, HLA-C, and HLA-DQ might have a relevant impact on the development of PJI. The literature surrounding this topic is limited, but emerging transcriptomic and genome-wide association studies hold promise for identifying at-risk genes. This advancement could pave the way for incorporating genetic testing into preoperative risk stratification, enhancing personalized patient care.

Regulation of neuronal fate specification and connectivity of the thalamic reticular nucleus by the Ascl1-Isl1 transcriptional cascade

The thalamic reticular nucleus (TRN) is an anatomical and functional hub that modulates the flow of information between the cerebral cortex and thalamus, and its dysfunction has been linked to sensory disturbance and multiple behavioral disorders. Therefore, understanding how TRN neurons differentiate and establish connectivity is crucial to clarify the basics of TRN functions. Here, we showed that the regulatory cascade of the transcription factors Ascl1 and Isl1 promotes the fate of TRN neurons and concomitantly represses the fate of non-TRN prethalamic neurons. Furthermore, we found that this cascade is necessary for the correct development of the two main axonal connections, thalamo-cortical projections and prethalamo-thalamic projections. Notably, the disruption of prethalamo-thalamic axons can cause the pathfinding defects of thalamo-cortical axons in the thalamus. Finally, forced Isl1 expression can rescue disruption of cell fate specification and prethalamo-thalamic projections in in vitro primary cultures of Ascl1-deficient TRN neurons, indicating that Isl1 is an essential mediator of Ascl1 function in TRN development. Together, our findings provide insights into the molecular mechanisms for TRN neuron differentiation and circuit formation.

Transcription factor-dependent regulatory networks of sexual reproduction in Fusarium graminearum.

Transcription factors (TFs) involved in sexual reproduction in filamentous fungi have been characterized. However, we have little understanding of how these TFs synergize within regulatory networks resulting in sexual development. We investigated 13 TFs in Fusarium graminearum, whose knockouts exhibited abortive or arrested phenotypes during sexual development to elucidate the transcriptional regulatory cascade underlying the development of the sexual fruiting bodies. A Bayesian network of the TFs was inferred based on transcriptomic data from key stages of sexual development. We evaluated in silico knockout impacts to the networks of the developmental phenotypes among the TFs and guided knockout transcriptomics experiments to properly assess regulatory roles of genes with same developmental phenotypes. Additional transcriptome data were collected for the TF knockouts guided by the stage at which their phenotypes appeared and by the cognate in silico prediction. Global TF networks revealed that TFs within the mating-type locus (MAT genes) trigger a transcriptional cascade involving TFs that affected early stages of sexual development. Notably, PNA1, whose knockout mutants produced exceptionally small protoperithecia, was shown to be an upstream activator for MAT genes and several TFs essential for ascospore production. In addition, knockout mutants of SUB1 produced excessive numbers of protoperithecia, wherein MAT genes and pheromone-related genes exhibited dysregulated expression. We conclude that PNA1 and SUB1 play central and suppressive roles in initiating sexual reproduction, respectively. This comprehensive investigation contributes to our understanding of the transcriptional framework governing the multicellular body plan during sexual reproduction in F. graminearum.IMPORTANCEUnderstanding transcriptional regulation of sexual development is crucial to the elucidation of the complex reproductive biology in Fusarium graminearum. We performed gene knockouts on 13 transcription factors (TFs), demonstrating knockout phenotypes affecting distinct stages of sexual development. Using transcriptomic data across stages of sexual development, we inferred a Bayesian network of these TFs that guided experiments to assess the robustness of gene interactions using a systems biology approach. We discovered that the mating-type locus (MAT genes) initiates a transcriptional cascade, with PNA1 identified as an upstream activator essential for early sexual development and ascospore production. Conversely, SUB1 was found to play a suppressive role, with knockout mutants exhibiting excessive protoperithecia due to abnormally high expression of MAT and pheromone-related genes. These findings highlight the central roles of PNA1 and SUB1 in regulating other gene activity related to sexual reproduction, contributing to a deeper understanding of the mechanisms of the multiple TFs that regulate sexual development.

Antibiotic tolerance due to restriction of cAMP-Crp regulation by mannitol, a non-glucose-family PTS carbon source.

Enzyme-IIA (EIIAGlc, Crr) of the phosphotransferase system (PTS) connects the uptake of glucose-family sugars to the cAMP-Crp regulatory cascade; phosphorylated EIIAGlc enhances cAMP-Crp activity, which then contributes to the antibiotic-mediated accumulation of reactive oxygen species (ROS) and cell death. Defects in PTS cause antibiotic and disinfectant tolerance. We report that mannitol, a carbon source whose uptake does not use EIIAGlc, reduces antibiotic-mediated killing of Escherichia coli without affecting antibiotic minimal inhibitory concentration. Thus, mannitol promotes antibiotic tolerance. The tolerance pathway was defined by the loss of ciprofloxacin lethality from the deletion of ptsI (first gene in PTS), mtlA (mannitol-specific Enzyme-II), cyaA (cAMP synthase), and crp (cAMP receptor protein) but not crr (EIIAGlc). A crp* mutant, which encodes a constitutively active Crp that bypasses the need for cAMP activation, also decreased mannitol-mediated antibiotic tolerance, as did exogenous cAMP. Thus, inhibition of antibiotic lethality by mannitol involves both PTS-mediated mannitol uptake and suppression of cAMP-Crp action, independent of EIIAGlc. Mannitol suppressed the downstream antibiotic-mediated transcription of genes involved in NADH production and cellular respiration, expression of a superoxide reporter gene (soxS), and accumulation of antibiotic-mediated ROS. Similar phenomena were observed with mannose and sorbitol, demonstrating that non-glucose PTS carbon sources can cause antibiotic tolerance by a novel path that reduces the ROS-promoting activity of cAMP-Crp. The work emphasizes that antibiotic tolerance, which contributes to disease relapse and the need for prolonged antibiotic treatment, can result from commonly consumed carbohydrates. This finding, plus mutations that interfere specifically with antibiotic lethality, makes tolerance a high probability event.IMPORTANCEBacterial tolerance constitutes a significant threat to anti-infective therapy and potentially to the use of disinfectants. Deficiency mutations that reduce glucose uptake, central carbon metabolism, and cellular respiration confer antibiotic/disinfectant tolerance by reducing the accumulation of reactive metabolites, such as reactive oxygen species. We identified novel environmental generators of tolerance by showing that non-glucose carbohydrates, such as mannitol, mannose, and sorbitol, generate tolerance to multiple antibiotic classes. Finding that these sugars inhibit a universal, stress-mediated death pathway emphasizes the potential danger of compounds that block the lethal response to severe stress. Immediate practical importance derives from mannitol being a popular food sweetener, a treatment for glaucoma, and a dehydrating agent for treating cerebral edema, including cases caused by bacterial infection: antibiotic tolerance could contra-indicate the use of mannitol and related carbohydrates during antibiotic treatment. Overall, the work shows that the presence of sugars must be considered during antimicrobial and perhaps disinfectant use.

Vibrio cholerae CsrA controls ToxR levels by increasing the stability and translation of toxR mRNA.

Intestinal colonization and virulence factor production in response to environmental cues is mediated through several regulatory factors in Vibrio cholerae, including the highly conserved RNA-binding global regulatory protein CsrA. We have shown previously that CsrA increases synthesis of the virulence-associated transcription factor ToxR in response to specific amino acids (NRES) and is required for the virulence of V. cholerae in the infant mouse model of cholera. In this study, we mapped the 5' untranslated region (5' UTR) of toxR and showed that CsrA can bind directly to an RNA sequence encompassing the 5' UTR, indicating that the regulation of ToxR levels by CsrA is direct. Consistent with this observation, the 5' UTR of toxR contains multiple putative CsrA binding sequences (GGA motifs), and mutating these motifs disrupted the CsrA-mediated increase in ToxR. Optimal binding of CsrA to a defined RNA oligonucleotide required the bridging of two GGA motifs within a single RNA strand. To determine the mechanism of regulation by CsrA, we assayed toxR transcript levels, stability, and efficiency of translation. Both the amount of toxR mRNA in NRES and the stability of the toxR transcript were increased by CsrA. Using an in vitro translation assay, we further showed that synthesis of ToxR was greatly enhanced in the presence of purified CsrA, suggesting a direct role for CsrA in the translation of toxR mRNA. We propose a model in which CsrA binding to the 5' UTR of the toxR transcript promotes ribosomal access while precluding interactions with RNA-degrading enzymes.IMPORTANCEVibrio cholerae is uniquely adapted to marine environments as well as the human intestinal tract. Global regulators, such as CsrA, which help translate environmental cues into an appropriate cellular response, are critical for switching between these distinct environments. Understanding the pathways involved in relaying environmental signals is essential for understanding both the environmental persistence and the intestinal pathogenesis of this devastating human pathogen. In this study, we demonstrate that CsrA directly regulates the synthesis of ToxR, a key virulence factor of V. cholerae. Under conditions favoring high levels of active CsrA in the cell, such as in the presence of particular amino acids, CsrA increases ToxR protein levels by binding to the toxR transcript and enhancing both its stability and translation. By responding to nutrient availability, CsrA is perfectly poised to activate the virulence gene regulatory cascade at the preferred site of colonization in the human host, the nutrient-rich small intestinal mucosa.

Diverse roles of phytohormonal signaling in modulating plant-virus interaction.

Virus infection brings about changes in the transcriptome, proteome and metabolome status of the infected plant wherein substantial alterations in the abundance of phytohormones and associated components involved in their signaling pathways have been observed. In the recent years, extensive research in the field of plant virology has showcased the undisputable significance of phytohormone signaling during plant-virus interactions. Apart from acting as growth regulators, phytohormones elicit robust immune response, which restricts the viral multiplication within the plant as well as its propagation by vector. Interestingly, these pathways have been shown to not only act as isolated mechanisms but as complex intertwined regulatory cascades where, the cross-talk among different phytohormones and with other antiviral pathways takes place during plant-virus interplay. Viruses cleverly disrupt phytohormone homeostasis via their multifunctional effectors that seems to be smart approach adopted by viruses to circumvent phytohormone-mediated plant immune responses. In this review, we summarize the current understanding of role of phytohormone signaling pathways during plant-virus interaction in activating antiviral immune responses of plant and also, how viruses exploit these signaling pathways favoring their pathogenesis.

Evolutionary Analysis of the hnRNP Interactomes and Their Functions in Eukaryotes.

The heterogeneous nuclear ribonucleoproteins (hnRNPs) are central regulators of several fundamental biological processes across eukaryotes. hnRNPs have been implicated in transcriptional and post-transcriptional regulation, telomere maintenance, stem cell maintenance, among other processes in major model organisms. Though hnRNPs are known to be conserved in eukaryotes, the evolutionary conservation/diversification of their functions across species is yet to be understood. To this end, the present work employed computational analyses to identify potential hnRNP orthologs in eighty eukaryotic species, and their interactors. Subsequently, a comprehensive analysis of the biological processes influenced by hnRNP interactomes showed alternative splicing and splicing regulation to be commonly associated with most species, while a few processes were uniquely associated with particular species. Further studies of the clustering patterns of the top-ranking hub nodes of the hnRNP protein networks revealed a notable clustering pattern of hnRNP K orthologs from five species. Subsequent analysis of the genes with overrepresented hnRNP K target sites within their untranslated regions showed hnRNP K orthologs from humans and Ciona intestanilis to potentially target transcripts involved in membrane-related processes. Remarkably, the hnRNP K ortholog from Lottia gigantea was found to possibly regulate other RNA-binding proteins (RBPs), suggesting a regulatory cascade involving hnRNPs and other RBPs. Further experimental studies in this regard would be of scientific and clinical importance, owing to the druggability of several human hnRNPs.

TMIC-87. ICAM-1 REGULATE EXTRACELLULAR VESICLE-MEDIATED IMMUNOSUPPRESSIVE MONOCYTE IN HUMAN GLIOBLASTOMA CELL

Abstract Glioblastoma is the most common malignant primary brain tumor and is universally fatal. Treatment involves maximal safe resection with adjuvant chemoradiation. Poor prognosis in glioblastoma is multifactorial, and local and systemic immunosuppression is an important factor. Extracellular vesicles (EVs) are small, membrane-bound particles released by cells into the external environment. They play a key role in intercellular communication. In glioblastomas, EVs regulate immunosuppression through induction of myeloid-derived suppressor cells (MDSCs) in a process dependent on the PD-1/PD-L1 and IL-6 axes. Primary cilia are microtubule-based organelles that play crucial roles in various cellular processes and signal transduction cascades. We recently showed that primary cilia modulate IL-6 expression and consequently, MDSC induction. Comparative proteomic analysis of EVs derived from human glioblastoma cells devoid of cilia showed loss of ICAM-1 expression compared to control glioblastoma cells. ICAM-1 (Intercellular Adhesion Molecule-1) is a cell surface glycoprotein that mediates cell-cell adhesion and immune responses. In this study, we showed that depletion of primary cilia in human glioblastoma cells result in increased PD-L1 but loss of IL-6 and ICAM-1. RNAi-meidated loss of ICAM-1 was synergistic with primary cilia depletion in preventing MDSC inductionn normal human monocytes exposed to glioblastoma-derived EVs. Exogenous IFN-g was sufficient to restore IL-6 levels and MDSC induction despite loss of primary cilia and ICAM-1 suggesting that primary cilia act upstream of IFN-g, IL-6 and ICAM-1 in glioblastoma-mediated MDSC induction. This study is the first to connect primary cilia signal transduction to IL-6 and ICAM-1 expression and to MDSC induction. The evidence suggests a potential parallel primary cilia regulatory cascade independent of the PD-L1 axis that controls tumor-mediated immunosuppression. These results may inform novel therapeutic strategies aimed at increasing efficacy of immunotherapy in the glioblastoma and other neoplastic processes.

Multi-organ gene expression analysis and network modeling reveal regulatory control cascades during the development of hypertension in female spontaneously hypertensive rat.

Hypertension is a multifactorial disease with stage-specific gene expression changes occurring in multiple organs over time. The temporal sequence and the extent of gene regulatory network changes occurring across organs during the development of hypertension remain unresolved. In this study, female spontaneously hypertensive (SHR) and normotensive Wistar Kyoto (WKY) rats were used to analyze expression patterns of 96 genes spanning inflammatory, metabolic, sympathetic, fibrotic, and renin-angiotensin (RAS) pathways in five organs, at five time points from the onset to established hypertension. We analyzed this multi-dimensional dataset containing ~15,000 data points and developed a data-driven dynamic network model that accounts for gene regulatory influences within and across visceral organs and multiple brainstem autonomic control regions. We integrated the data from female SHR and WKY with published multiorgan gene expression data from male SHR and WKY. In female SHR, catecholaminergic processes in the adrenal gland showed the earliest gene expression changes prior to inflammation-related gene expression changes in the kidney and liver. Hypertension pathogenesis in male SHR instead manifested early as catecholaminergic gene expression changes in brainstem and kidney, followed by an upregulation of inflammation-related genes in liver. RAS-related gene expression from the kidney-liver-lung axis was downregulated and intra-adrenal RAS was upregulated in female SHR, whereas the opposite pattern of gene regulation was observed in male SHR. We identified disease-specific and sex-specific differences in regulatory interactions within and across organs. The inferred multi-organ network model suggests a diminished influence of central autonomic neural circuits over multi-organ gene expression changes in female SHR. Our results point to the gene regulatory influence of the adrenal gland on spleen in female SHR, as compared to brainstem influence on kidney in male SHR. Our integrated molecular profiling and network modeling identified a stage-specific, sex-dependent, multi-organ cascade of gene regulation during the development of hypertension.

Understanding cold stress response mechanisms in plants: an overview.

Low-temperature stress significantly impacts plant growth, development, yield, and geographical distribution. However, during the long-term process of evolution, plants have evolved complicated mechanisms to resist low-temperature stress. The cold tolerance trait is regulated by multiple pathways, such as the Ca2+ signaling cascade, mitogen-activated protein kinase (MAPK) cascade, inducer of CBF expression 1 (ICE1)-C-repeat binding factor (CBF)-cold-reulated gene (COR) transcriptional cascade, reactive oxygen species (ROS) homeostasis regulation, and plant hormone signaling. However, the specific responses of these pathways to cold stress and their interactions are not fully understood. This review summarizes the response mechanisms of plants to cold stress from four aspects, including cold signal perception and transduction, ICE1-CBF-COR transcription cascade regulation, ROS homeostasis regulation and plant hormone signal regulation. It also elucidates the mechanism of cold stress perception and Ca2+ signal transduction in plants, and proposes the important roles of transcription factors (TFs), post-translational modifications (PTMs), light signals, circadian clock factors, and interaction proteins in the ICE1-CBF-COR transcription cascade. Additionally, we analyze the importance of ROS homeostasis and plant hormone signaling pathways in plant cold stress response, and explore the cross interconnections among the ICE1-CBF-COR cascade, ROS homeostasis, and plant hormone signaling. This comprehensive review enhances our understanding of the mechanism of plant cold tolerance and provides a molecular basis for genetic strategies to improve plant cold tolerance.

Unexpected proteins involved in the regulation of secondary metabolism in Myxococcus xanthus DK1622.

Regulating secondary metabolite (SM) in Myxococcus xanthus bears the potential to influence the formation of important natural products with various biological activities. The authors of this study have previously found that the detectable levels of two proteins (4-hydroxyphenylpyruvate dioxygenase [HppD] and a Hsp90-like protein [HtpG]) are affected by ROK inactivation. As evidence, the current study was designed to elucidate the possible role of these two proteins in regulating the SMs' biosynthesis in this bacterium. To begin with, inactivation of the corresponding genes was carried out, and two mutant strains (M. xanthus hppD- and htpG-) were constructed. Subsequently, high-performance liquid chromatography coupled with mass spectrometry analysis for the metabolic extracts of the mutants revealed a significant reduction in the production of several SMs, like DKxanthene, myxalamide A, and myxochromide A, in comparison to the wild type. Furthermore, electrophoretic mobility shift assays using purified ROK protein suggested a direct binding on the genes' promoter region encoding the two proteins under study. It is therefore possible to conclude that hppD and htpG genes are implicated in the bacterium SMs' biosynthetic regulatory cascade, which seems to be directly regulated by the ROK protein. The present study provides additional evidence to a previous investigation showing the pleiotropic regulatory role of ROK on the production of SMs in M. xanthus.

The pathogenicity-associated regulators participating in the regulatory cascade for RaxSTAB and RaxX in Xanthomonas oryzae pv. oryzae.

The RaxX sulfopeptide, secreted via a type Ι secretion system, is crucial for activating XA21-mediated innate immunity in resistant rice lines bearing the XA21 receptor kinase. Certain pathogenicity-associated regulators that control the expression of the raxSTAB-raxX gene cluster have been functionally characterized, but the comprehensive regulatory cascade of RaxSTAB and RaxX in Xanthomonas oryzae pv. oryzae (Xoo) remains incompletely understood. Our investigation revealed that pathogenicity-associated regulators, including HrpG, HrpX, VemR, PhoR, and Clp, form a regulatory cascade governing the expression of the raxSTAB-raxX gene cluster. HrpG regulates the raxSTAB-raxX gene cluster transcription through the key regulator HrpX. VemR also participates in the transcription of the raxSTAB-raxX. The histidine kinase PhoR positively modulates raxSTAB-raxX expression, while the global regulator Clp directly binds the raxX promoter region to promote its transcription. These findings shed light on the intricate regulatory cascade of rax-related genes in Xoo, emphasizing the complex roles of pathogenicity-associated regulators within the pathogenic regulatory system.

Clinical characteristics and genomic changes of recurrent Methicillin‐Resistant Staphylococcus aureus bacteremia

BackgroundRecurrent or persistent methicillin-resistant Staphylococcus aureus (MRSA) bacteremia presents significant clinical challenges. Comprehensive genomic-scale studies on the genetic changes in MRSA that correspond to refractory bacteremia are lacking. MethodFrom 2011 to 2019, MRSA blood isolates were collected from patients with persistent or recurrent bacteremia at a teaching hospital in southern Taiwan. Whole-genome sequencing (WGS) captured the genomic changes in strains responsible for refractory bacteremia, and the altered susceptibilities to specific antimicrobial agents were assessed through measurements of minimal inhibitory concentrations (MICs). ResultA total of 35 MRSA blood isolates from 15 patients with recurrent or persistent bacteremia were analyzed. Reduced susceptibilities to at least one anti-MRSA agent developed in strains from seven (46.7 %) patients. Of them, a non-synonymous mutation on a global regulator mgrA was associated with reduced daptomycin susceptibility, while an increase in vancomycin MIC was linked to mutations in genes encoding LCP family protein. A 16-fold increase in MIC to fusidic acid was connected to a mutation in the elongation factor G. These recurrent strains commonly exhibited a loss or acquisition of adhesion genes that were involved in biofilm formation, including fnbA, fnbB, and sdrD, and easG series genes of type VII secretion system. ConclusionChanges in the susceptibility of successive strains to common anti-MRSA agents were frequently observed in recurrent MRSA bacteremia. These changes were linked to modifications in genes of regulatory cascade, peptidoglycan binding, adhesion, and type VII secretion system.

Acute myocardial infarction leads to distinct sex differences in the coding transcriptome of human monocytes with a potential impact in disease aetiopathology

Abstract Background Immune responses are intricately linked to human disease, not only during pathogenic infections but also in sterile injury events such as in cardiovascular disease. Atherosclerosis is the main driver leading to coronary artery disease (CAD) and subsequent development of acute myocardial infarction (AMI) and heart failure. The vital role of monocytes in the pathophysiology of atherosclerosis is well established. In the onset of AMI, monocytes act as first responders, both in the inflammatory and tissue repair phases. It is now apparent that sex-specific differences in the inflammatory responses leading to AMI impact the severity and outcome of patients. Yet, the immune responses during AMI have been under-investigated in women, often under-represented in clinical studies, and more research in this topic is required. Purpose Identification of sex-specific differences in the coding transcriptome of monocytes subpopulations in the onset of AMI compared to matched healthy subjects and CAD patients. Methods We isolated monocytes from male and female AMI patients, CAD patients and healthy controls. FACS sorting of monocytes (CD14 and CD16) resulted into classical, intermediate, and non-classical subpopulations. We performed ribosomal depletion and bulk Illumina RNA sequencing for each monocyte subpopulation. Differentially expressed genes (DEG) were calculated using specific R packages. Pathway enrichment analysis was performed with Gene set enrichment analysis (GSEA). Other computational tools were used to determine enrichment of genes linked to GWAS identified in cardiovascular diseases or to infer pathway responsive genes upon perturbation (Progeny). Network comparison and visualization were performed using Cytoscape platform. Results Whereas observing a clear overlap of most pathways such as homeostasis, regulation of signalling cascades and inflammatory response, we also identified other pathways contrasting strongly between both sexes. In fact, TGF beta/ SMAD signalling, wound healing and epithelial to mesenchymal transition are increased in female cells. On the contrast the more pro-inflammatory BMP/SMAD signalling is increased in male cells accompanied by decreased respiratory electron transport and translation. Additionally, when comparing our data to signatures identified in trauma patients, we observe clear mapping of our gene sets, which are upregulated in AMI, with the first 3 trauma associated signatures, whereas one of the signatures associated to homeostasis associates clearly with our CAD data as well as the healthy subjects. Conclusions Human monocytes display a specific coding transcriptome and certain pathways are differentially expressed in AMI and differ greatly between male and female cohorts. Interestingly, our DEG map closely to trauma associated signatures, highlighting potential similarities in disease aetiopathology between trauma and AMI patients.

The Neglected Suppressor of Cytokine Signalling (SOCS): SOCS4-7.

SOCS proteins are essential for the regulation of oncogenic, anti-pathogenic, and proinflammatory signalling cascades, including the JAK/STAT and NF-kB pathways, where they act as negative feedback regulators. Given their powerful role in a broad spectrum of biological processes, it is surprising that the functions of many SOCS proteins have not been widely explored. While the mechanisms of action of CIS, SOCS1-3 are well-documented, information regarding SOCS4-7 remains limited. However, recent studies have begun to elucidate the regulatory functions of these proteins during infection and disease, such as influenza infection, cancer and diabetes. Therefore, this review aims to describe and discuss studies detailing our current understanding of SOCS4-7, painting a clearer picture of the biological processes these regulatory proteins maintain. Indeed, our review highlights important evidence proving that all SOCS play a role in biological processes that are essential for normal immunological homeostasis, clearance of infection and avoidance of disease. Understanding how SOCS proteins interact with other proteins or how they are dysregulated in disease is likely to provide valuable insights for advancing therapeutic approaches.

Plant Rho GTPase ROP6 Is Essential for Manganese Homeostasis in Arabidopsis.

Manganese (Mn) is an indispensable mineral for plant growth and development. However, plants cultivated in acidic and poorly drained soils are vulnerable to Mn2+ toxicity due to its heightened increased bioavailability. Despite the crucial roles of the Rho of plant (ROP) GTPases in various cellular processes, their precise function in regulating Mn homeostasis remains elusive. In this study, we unveil a novel ROP6 GTPase signalling pathway that profoundly influences Mn phytotoxicity tolerance in Arabidopsis. Remarkably, the rop6 and dominant-negative ROP6 (rop6DN) mutant plants displayed a dramatically sensitive phenotype to Mn toxicity, whereas ROP6-overexpression and constitutively activated ROP6 (rop6CA) lines exhibited enhanced Mn stress tolerance. Immunoblot analysis corroborated that the ROP6 protein, especially the active form of ROP6, increased in abundance in the presence of high Mn levels. Further, we identified that ROP6 physically interacted and colocalized with Metal Tolerance Protein 8 (MTP8) in vivo. Mn transport complementation assays in yeast, combined with biochemical analyses, emphasized the essentiality of ROP6 for MTP8's transport activity. In addition, genetic analyses indicated that ROP6 acted upstream of MTP8 in the regulatory cascade. Collectively, our findings elucidate that ROP6 GTPase signalling positively modulates and enhances Mn stress tolerance in plants.

TMSB4Y restrains sphingomyelin synthesis via de novo purine synthesis to exert a tumor suppressor function in male esophageal squamous cell carcinoma.

Y chromosome genes play a vital role in sex difference of cancer. The dysregulation and functional implications of Y chromosome genes in esophageal squamous cell carcinoma (ESCC) remains elusive. Here, we analyze the Y chromosome gene signature and identify TMSB4Y as an emerging prognostic predictor in male ESCC. Functional analyses show that TMSB4Y inhibits the proliferation, invasion and metastasis of male ESCC cells. Mechanistically, we demonstrate that TMSB4Y interacts with PAICS, wherein TMSB4Y disrupts the formation of the PAICS octamer to inhibit purine de novo synthesis, leading to a decrease in the AMP/ATP ratio, subsequently impeding AMPK phosphorylation. Furthermore, we uncover a regulatory cascade orchestrated by the TMSB4Y/PAICS-AMPK axis, which exerts a suppressive effect on sphingomyelin metabolism by inhibiting the expression of sphingomyelin synthases (SMSs). Notably, Malabaricone C, an inhibitor of SMS1 and SMS2, effectively suppresses male ESCC cell proliferation and xenograft tumor growth. Collectively, these findings reveal the regulation of sphingomyelin metabolism by TMSB4Y/PAICS-AMPK axis and underscore the potential of targeting SMSs as a promising therapeutic approach for the treatment of male ESCC.

The MaNAP1-MaMADS1 transcription factor module mediates ethylene-regulated peel softening and ripening in banana.

The banana (Musa spp.) peel undergoes rapid softening during ripening, leading to finger drop and a shortened shelf life. The regulatory mechanism behind this process remains to be elucidated. In this study, we confirmed the role of peel softening in banana finger drop and uncovered the underlying transcriptional regulatory network. Cell wall-related (CWR) genes were substantially upregulated in both the peel and finger drop zone during ethylene-induced ripening. Transcriptome analysis and genome-wide profiling of chromatin accessibility and transcription factor (TF) binding revealed that two key regulators of fruit ripening, Musa acuminata NAC-like, Activated by apetala3/Pistillata1 (MaNAP1) and MaMADS1, regulate CWR genes by directly binding to their promoters or by targeting other ripening-related TFs to form a hierarchical regulatory network. Notably, MaNAP1 and MaMADS1 were directly targeted by ETHYLENE INSENSITIVE3 (MaEIN3), and MaNAP1 and MaMADS1 associated with tissue-specific histone modifications, enabling them to integrate MaEIN3-mediated ethylene signaling and undergo epigenetic regulation. Overexpression of MaNAP1, MaMADS1 or other identified regulatory TFs upregulated CWR genes and promoted peel softening. Our findings unveil a MaNAP1-MaMADS1-centered regulatory cascade governing banana peel softening and finger drop, offering potential targets for enhancing banana texture and shelf life.

Negative regulation of APC/C activation by MAPK-mediated attenuation of Cdc20Slp1 under stress

Mitotic anaphase onset is a key cellular process tightly regulated by multiple kinases. The involvement of mitogen-activated protein kinases (MAPKs) in this process has been established in Xenopus egg extracts. However, the detailed regulatory cascade remains elusive, and it is also unknown whether the MAPK-dependent mitotic regulation is evolutionarily conserved in the single-cell eukaryotic organisms such as fission yeast (Schizosaccharomyces pombe). Here, we show that two MAPKs in S. pombe indeed act in concert to restrain anaphase-promoting complex/cyclosome (APC/C) activity upon activation of the spindle assembly checkpoint (SAC). One MAPK, Pmk1, binds to and phosphorylates Slp1Cdc20, the co-activator of APC/C. Phosphorylation of Slp1Cdc20 by Pmk1, but not by Cdk1, promotes its subsequent ubiquitylation and degradation. Intriguingly, Pmk1-mediated phosphorylation event is also required to sustain SAC under environmental stress. Thus, our study establishes a new underlying molecular mechanism of negative regulation of APC/C by MAPK upon stress stimuli, and provides a previously unappreciated framework for regulation of anaphase entry in eukaryotic cells.